EP0187795B1 - Sector with variable thickness for a disc-type rotary filter - Google Patents

Abstract

Filtering sector intended to form a filtering disc comprising a rigid frame imparting the form thereto, filtering cloth supports inside the frame and a connection part for connecting a rotary filter to a hollow drive shaft (2), said shaft containing connectors of liquid and gas fluids, the sector being characterized in that its internal thickness increases from the peripheral end thereof (14) up to the end (15) thereof at the vicinity of the hollow drive shaft (2).

Description

The invention relates to sectors of variable thickness intended to constitute a rotary filter disc which may comprise several discs.

It has long been known to carry out the separation by filtration of a continuous phase, liquid or gaseous, and a dispersed phase, solid or liquid, initially forming a suspension resulting, for example, from the attack of a ore.

To do this, the suspension is brought above a support, such as grid, canvas, membrane, etc. on which the solid particles are deposited, forming a cake of variable thickness, while the liquid phase constituting the filtrate, passes through the filtration texture and is then collected by any collection means.

Depending on the characteristics of the suspensions to be filtered, such as for example the concentration of dry matter, the size of the solid materials, the ability to separate, the aggressiveness of the medium, the degree of classification required, the person skilled in the art is led to choose an appropriate device among the many technologies offered on the market.

Among these filtration technologies described in the specialized literature, one of them is very often used and appreciated in the field of the separation of the liquid and solid phases of suspensions resulting from attacks of ores according to hydrometallurgical processes: this technology concerns rotary disc filters, such as those described for example in "Chemical Engineer's Handbook", page 978, by John H. PERRY, Edition No. 5 Graw Hille Book Company, 1950.

As described, rotary disc filters include a plurality of discs fixed perpendicular to a hollow horizontal shaft, made up of channels in which various effects are practiced such as, suction, blowing ... Each disc is made up of several independent sectors furnished with metal fabrics and / or filtering textile bags, connected to the aforementioned hollow horizontal shaft.

During the filtration operation, the discs, fitted with their sectors, plunge into a trough containing the suspension to be filtered, the solid phase being glued by suction to the filter cloths, while the separated liquid phase flows into the collectors of the horizontal shaft provided with at least one distributor, by means of connections existing between each sector and the shaft itself. The solid phase placed on the filter cloth is then wrung during the passage to the open air, then eliminated by blowing air against the current through the filtering surfaces.

However, it is well known that each rotary disc is formed of sectors, each consisting of a rigid frame giving the shape to the sector, this frame containing the filter cloth support and a connecting piece to the hollow collecting shaft and drive.

According to known art, the canvas support is generally formed from perforated metallic materials, such as for example perforated, flat or corrugated sheet, in order to present the minimum of contact with the filter cloth. Thus, each sector face is provided with a canvas support. And these two canvas supports, inserted into the reinforcement of the sector are held together, at a constant distance, by spacers fixing the internal thickness of the sector, this internal thickness being defined by the quantity of liquid phase to be evacuated by the base. of the sector, that is to say near the tree, where the width of said sector is the smallest. In other cases, the two canvas supports and the spacers which connect them can consist, for example, of a single corrugated sheet, the corrugation height of which constitutes the internal thickness of the sector necessary for the flow of the liquid phase. .

However, such sectors, with constant thickness, have the major drawback of having a substantial internal volume containing a large amount of the liquid phase, which is removed during the spinning step simultaneously with the fraction of liquid phase permeating the solid phase deposited on the faces of the sector. However, the step of wringing out the liquid phase, fixed by the filtration step and the physical position of the sector at the time of blowing, is generally insufficient to allow complete evacuation of the liquid phase present in the sector. And as soon as the blowing step takes place, the fraction of the aqueous phase still in the sector is sprayed through the filter cloths, rewetting the solid phase still present on the canvas. Thus, the spin efficiency is reduced.

However, such sectors of constant thickness also have another major drawback. Indeed, even if the duration of the spinning step is sufficient to remove from the sector all of the liquid phase, initially present and originating from the spinning, it is often found that part of this liquid phase is still present in the tree collector at the time of blowing. The presence of this liquid phase causes a reduction in cross section of the manifold for the passage of air, thereby increasing the pressure drops and thereby reducing the efficiency of the blowing. It is certain that such a drawback can be limited by increasing the diameter of the collector or else by the inclination of the collector. But these two possibilities lead to the appearance of a new drawback which is the increase in the diameter of the collection and drive shaft and of all the technology associated with it, such as distributor, bearings and sealing of the tree in the passage of the tank.

Also known from document US-A-3 438 505 is a sector whose thickness is decreasing from the center towards the periphery and the internal structure formed in particular by a rigid reinforcement canvas support at the same time acting as a collector and filterat exhaust pipe. The embodiment described in this document is a sector in which the variation in thickness not specified is small.

The filtration sector according to the invention, with a view to constituting a filtration disc comprising a rigid frame giving it shape, supports of filtration cloth inside the frame and a connection piece to a hollow shaft of driving a rotary filter, said shaft containing liquid and gaseous fluid collectors, said sector being of increasing internal thickness from its peripheral end to its end in the vicinity of the hollow drive shaft is characterized in that the internal thickness "e _o " of the sector at its peripheral end (14) responds to the inequality 0 6 e _o ≤ e / 10 in which "e" is the thickness of the sector at the neighboring end of the tree drive (2).

As in the prior art, the internal thickness in the vicinity of the shaft is determined to offer a sufficient section for the evacuation of the liquid phase of impregnation of the solid phase deposited on the canvas of the sector and of the quantity of liquid phase contained in the sector, which is frequently less than the quantity of liquid phase contained in a sector of the prior art of the same dimensions but having a constant thickness.

As in the prior art, the quantity of the liquid phase to be evacuated by the section of the sector at its periphery is practically zero.

According to the invention, the internal thickness of the sector at its periphery which is identified by "e _o " can therefore be zero, if the canvas supports consist of flat surfaces for example.

To complete the knowledge relating to the invention, use is made of FIGS. 1 and 2 making it possible to carry out the comparison between a sector according to the prior art (FIG. 1) and a sector according to the invention (FIG. 2).

According to Figure 1, illustrating one aspect of the prior art, a filtration sector is in communication by an appropriate means (1) forming part of the sector with the collection and drive shaft (2) rotating around its geometric axis (3). This means of communication (1) is integral with a frame (4) inside which are placed on either side of the canvas supports (5), kept at constant distance from each other, giving the sector a thickness "e" (6) equal to the periphery (14) to the end (15) in the vicinity of the shaft (2). The internal section (7) of the sector offered for the passage of the liquid phase, contained in the sector is located at a distance "r" from the axis of rotation (3). This internal section (7) is defined by the width (8) of the sector in the vicinity of the shaft (2) and by the thickness "e" (6).

The section (9) at the periphery located at the distance "R" from the axis (3) is defined by the width of the sector (10) at the periphery (14) and the thickness "e" (6).

The internal volume of such a sector can be calculated according to Guldin's theorem:

"If S is the area of a plane surface rotating around an axis located in its plane and not including it, the volume of revolution generated by this surface is V = 2 π RgS, Rg being the distance separating the center of gravity of the area S of the axis of rotation ".

n étant le nombre de secteurs formant un disque.Thus, in the case of FIG. 1, corresponding to the prior art, the surface Sa (11) is defined by the product of (Rr) and "e" (6). Its center of gravity (12) is located at a distance Rg _a equal to [(Rr) / 2 + r] from the axis of rotation (3). Thus, the internal volume Va of the sector in the case of the prior art is:

n being the number of sectors forming a disc.

According to Figure 2, illustrating the invention, a filtration sector is in communication by an appropriate means (1) forming part of said sector with the collection and drive shaft (2) rotating around its geometric axis (3) . This means of communication (1) is integral with a framework (13) inside which are placed on either side of the supporting canvas (5) concurrent, giving the sector an increasing thickness from the periphery (14 ) to the end (15) in the vicinity of the shaft (2). The internal section (7) of the sector offered for the passage of the liquid phase contained in the sector is the same as in the axis of rotation (3). This internal section (7) is defined by the width of the sector (8) in the vicinity of the shaft (2) and by the thickness "e" (6). Thus, the width (8) and the thickness "e" (6) are the same for the sectors of the prior art and of the invention. The section (16) at the periphery (14) located at the distance "R" from the axis (3) is defined by the width (10) of the sector at said periphery and by the thickness "e _o " (17) .

de l'axe de rotation (3). Ainsi, le volume interne V; du secteur dans le cas de l'invention est:

dans laquelle n est toujours le nombre de secteurs constituant le disque.The internal volume V; of such a sector is also calculated according to Guldin's theorem. Thus, in the case of FIG. 2, corresponding to the invention, the surface Si (18) is defined by the product of (Rr) and (e _o + e) / 2. Its center of gravity (19) is located at a distance Rg _(i) equal to:

of the axis of rotation (3). Thus, the internal volume V; of the sector in the case of the invention is:

in which n is always the number of sectors making up the disk.

According to a variant, corresponding to the particular case where "e _o " is zero, the internal volume V; is determined by the relation:

From then on, it appears between the internal volumes sectors V; according to the invention and Va, according to the prior art, a ratio V _{i /} V _a which responds to the inequality:

révélant ainsi que le volume interne V; d'un secteur selon l'invention est toujours inférieur au volume interne Va du même secteur selon l'art antérieur, c'est-à-dire à épaisseur "e" constante. Selon la variante, correspondant au cas particulier où "e" est nul, ce rapport des volumes V_i/V_a répond à l'égalité:

thus revealing that the internal volume V; of a sector according to the invention is always less than the internal volume Va of the same sector according to the prior art, that is to say of constant thickness "e". According to the variant, corresponding to the particular case where "e" is zero, this ratio of the volumes V _i / V _a corresponds to equality:

Thanks to the sector according to the invention, it is possible to better size the manifolds and the shaft of a rotary disc filter to obtain a faster evaluation of the liquid phase and better blowing efficiency.

Example (illustrated by figures 1 to 5)

As part of the research and development of a filtration sector for increasing thickness disc filter "e _o " from the periphery (14) to the end (15) of thickness "e" in the vicinity of the tree (2), the applicant has studied two sectors having the same filtration surface and the same passage section, one of constant thickness "e" belonging to the prior art (fig. 1) , the other of variable thickness belonging to the invention (fig. 2).

The characteristics of the sections were as follows:

The internal volume Va of the sector according to the prior art was 19.63 liters while the internal volume V; of the sector according to the invention was 7.85 liters.

The filter on which were mounted sectors forming 50% immersed discs, rotated at the speed of 3 revolutions per minute in order to achieve a productivity in liquid phase of 3000 Iitres.h.- ¹ .m2.

Under these conditions, the quantity of the liquid phase passing through the filter cloth during the filtration and spinning stages corresponding to a rotary kiln, was equal to 13.88 liters.

From flow rate measurements of the liquid phase operated on a disc filter, by varying the dry matter content of the suspension to be filtered, so as to obtain on the filtration fabric sectors of different thicknesses from the solid phase deposited , we were able to establish the cumulative flow curve (A) (fig. 3) of the aqueous phase through the progressively charged filter cloth, brought back to the filtration surface of a sector. The abscissa axis y "in degrees" represents, on a first scale, a 360 ° revolution of a sector, on a second scale, the times "t" in seconds corresponding to a revolution in 20 seconds (3 turns / minute) and also the steps aF corresponding to the filtration angle, aE corresponding to the spin angle, aS corresponding to the blowing angle and aM non-productive dead angle, the sum of these angles corresponding to one revolution. . The ordinate axis represents in liters the cumulative flow rate of the liquid phase passing through a sector and this internal volume of the different sectors studied.

As can be seen on this curve (A), the flow rate of the liquid phase, through the filter cloth and passing through the interior of the sector is greater at the start of the filtration step aF than at end, due to the inexistence or thinness of the solid phase on the canvas at the start of this stage and its maximum thickness at the end.

Similarly, it can be noted that during the spinning step λE, the flow rate of the liquid phase through the fabric is low since it corresponds to the evacuation of part of the liquid phase present in the solid phase on Web.

From this curve, we were able to determine the influence that the internal volume of a sector can have on the instant when the sector begins to pour into the collectors of the tree the liquid phase which crosses it and on the instant when the interior of the sector is rid of the liquid phase which passed through it.

According to the sector of the prior art having an internal volume of 19.63 liters (reference B), it has been observed that the internal volume of this sector was never completely filled with the liquid phase which passes through it and that according to the FIG. 4 the beginning of the evacuation of this liquid phase begins to take place when said sector has already embraced an angle "y" of approximately 172.5 ° relative to its starting position (for which y is equal to 7, 5 °).

Figure 4 associated with Figure 3 illustrates the beginning of the evacuation of the liquid phase. Indeed, if we consider the position (30) starting from a sector which has just been immersed with respect to the level DD 'of the suspension in the trough (37) (corresponding to an immersion of 50% of the drive shaft (32)), this position (30) corresponds to an angle y which is well equal to 7.5 °, when the disc (32) consists, for example, of 24 sectors having an angle at the top 15 °. When the sector (30) comes into position (33), it has already embraced an angle of 172.5 ° relative to its starting position and the angle y measured in the direction of rotation of the disc (32) is then of 180 °. Beyond y = 180 °, the sector occupies the position (34) corresponding to the angle spin aE. Then, in position (35), it enters the blowing zone corresponding to the angle as, during which the cake deposited on the faces of the sector is deflected by the deflectors (36). Finally, the sector (35) enters a non-productive area, represented by the angle aM.

According to FIG. 1, from the angle y = 7.5 ° for which the filtration step aF begins and up to the angle y = 180 ° corresponding to the end of the filtration step aF, the sector ( B) of the prior art receives without spilling the quantity of the liquid phase passing through the fabric, represented by (A) and from y = 180 °, this sector begins to pour into the collectors of the tree the liquid phase that 'it contains, during an evacuation time along the line B1, the slope of which has been determined beforehand by experience on a moving sector. Line B1 corresponds to the cumulative flow rate of the evacuation of the liquid phase stored in the sector from y = 7.5 ° to y = 180 °, to which must be added the flow rate of the liquid spin phase starting at y = 180 ° and giving the line of the accumulated flows B2.

Thus, it appears that the evacuation of the liquid phase passing through the sector risks prolonging up to y = 350 °, thus covering the whole of the spinning step aE and intercepting the blowing step aS by causing the displacement of the aqueous phase in this sector and the rewetting on canvas of the drained solid phase.

According to a sector (C) of the invention for e _o = 0, and of internal volume 7.85 liters, it has been observed that the sector began to fill at the start of the filtration stage for y = 7.5 ° and that according to the curve of the cumulative flows (A), it was completely filled for y = 47.5 °. FIG. 5 shows that such a sector entirely filled with aqueous phase begins to pour gravity this phase into the tree when it reaches position (33) for the angle y = 172.5 °, as it began to fill as in the prior art and according to position (30) for the angle y = 7.5 °. In fact, this sector was already full when it occupied the position (38) corresponding to the angle y = 47.5 °, that is to say that the excess of liquid phase was already flowing at this time in the shaft collector (40).

According to FIG. 3, from the position corresponding to the angia y = 172.5 °, the sector empties of the liquid phase according to a cumulative flow illustrated by the line C1 of slope close to the slope of the line B1. To this cumulative flow must be added on the one hand the flow corresponding to the end of filtration for 172.5 ° <y <180 ° and on the other hand the flow of the liquid spin phase starting for the angle y = 180 ° and giving the line of the cumulated flows C2.

Thus, it has been observed that the evacuation of the liquid phase passing through the sector is completed for the value of the angle y = 270 °, that is to say well before the blowing step aS begins. .

As soon as the sector according to the invention is emptied of all the liquid phase for the angle y = 270 °, it is noted that the liquid phase still present in the collector is evacuated before the blowing step begins, increasing the efficiency of blowing and avoiding rewetting of the solid phase on the filter cloth.

• - pour l'art antérieur, des positions y = 180° à y = 330°, représentant un temps d'évacuation compris entre 10 et 18,3 secondes, c'est-à-dire l'évacuation de 13,88 litres en 8,3 secondes.
• - pour l'invention, des positions y = 47,5° à y = 270°, représentant un temps d'évacuation compris entre 2,6 et 15 secondes, c'est-à-dire l'évacuation de 13,88 litres en 12,4 secondes.

The comparison between the sectors of the prior art (B) and of the invention (C) shows that the liquid phase passing through this sector is discharged into the tree:

• - for the prior art, positions y = 180 ° to y = 330 °, representing an evacuation time of between 10 and 18.3 seconds, that is to say the evacuation of 13.88 liters in 8.3 seconds.
• - for the invention, positions y = 47.5 ° to y = 270 °, representing an evacuation time of between 2.6 and 15 seconds, that is to say the evacuation of 13.88 liters in 12.4 seconds.

According to a sector (D) of the invention, for which e _o = e / 10, and of internal volume 9.81 liters, it was also possible to observe that the sector began to fill up at the start of the filtration stage for y = 7.5 ° and that following the curve of the cumulative flows (A), it was completely filled for y = 77.5 ⁰ . Figure 5 shows that such a sector, entirely filled with aqueous phase, begins to pour gravity this phase into the tree when it reaches position (33) for the angle y = 172.5 °, while it began to fill as in the prior art and according to position (30) for the angle y = 7.5 °. In fact, this sector was already full when it occupied the position (39) corresponding to the angle y = 77.5 °, that is to say that the excess of liquid phase was already flowing at this time in the tree collector.

According to FIG. 3, from the position corresponding to the angle y = 172.5 °, the sector empties of the liquid phase, according to a cumulative flow illustrated by the line D1 with a slope close to the slope of the line C1. To this accumulated flow D1 must be added the flow of the liquid spin phase starting for the angle y = 180 ° and giving the line of the accumulated flows D2.

Thus, it has been observed that the evacuation of the liquid phase passing through the sector ends for the value of the angle 290 °, that is to say before the blowing step aS begins.

As soon as the sector according to the invention is drained of all the liquid phase for the angle y = 290 °, it is noted that the liquid phase still present in the collector is evacuated before the blowing step begins, increasing the efficiency of blowing and avoiding rewetting of the solid phase on the filter cloth.

• - pour l'art antérieur, des positions y = 180° à y = 330°, représentant un temps d'évacuation compris entre 10 secondes et 18,3 secondes, c'est-à-dire l'évacuation de 13,88 litres en 8,3 secondes.
• - pour l'invention, des positions y = 77,5° à y = 290° représentant un temps d'évacuation compris entre 4,3 et 16,11 secondes, c'est-à-dire l'évacuation de 9,81 litres en 11,81 secondes.

Thus, the comparison between the sectors of the prior art (B) and of the invention (D) shows that the liquid phase passing through the sector is discharged into the tree:

• - for the prior art, positions y = 180 ° to y = 330 °, representing an evacuation time between 10 seconds and 18.3 seconds, that is to say the evacuation of 13.88 liters in 8.3 seconds.
• - for the invention, positions y = 77.5 ° to y = 290 ° representing an evacuation time of between 4.3 and 16.11 seconds, that is to say the evacuation of 9.81 liters in 11.81 seconds.

Consequently, there appears little difference between the evacuation times between the sectors (C) and (D) of the invention, while noting however that the end of the emptying of the sector (D) is closer to the blowing aS as the sector (C), thus reducing the evacuation time of the collectors.

Claims (2)

1. A filtration sector for making up a filtration disc for rotary filter comprising a rigid frame imparting its shape thereto, supports for filter cloth within the frame and a member for connection to a hollow drive shaft (2) containing liquid and gaseous fluid collectors, said sector being of an increasing thickness from its peripheral end (14) to its end (15) in the vicinity of the hollow drive shaft (2), characterised in that the internal thickness "e_o" of the sector at its periphery (14) corresponds to the inequality

wherein "e" is the thickness of the sector at the end in the vicinity of the driveshaft (2).

2. A filtration sector for making up a disc of rotary filter according to claim 1, characterised in that the internal section (7) of the sector which is afforded to the flow of liquid phase contained in the sector, being defined by the width (8) of the sector in the vicinity of the shaft (2) and by the thickness "e", is the same as in the axis of rotation (3).

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